[0001] This invention relates to low cost magnetic disks for use as memory storage devices,
and more particularly pertains to such devices made up of multiple layers of thin-films
with the magnetic layer being nickel cobalt.
[0002] The speed of modern computers has increased at least a hundredfold in recent years,
often at the same or less cost than those devices which came before. That progress
has been supported in many ways by progress in other technologies, such as in data
storage devices. To support that progress, special demands have been made as to the
characteristics of these magnetic media in regard to recording densities, so that
densities of as much as 10
7 bits per square inch can now be achieved for some hard disks. Such demands, however,
have required that special techniques be developed for manufacturing such disk memory
devices and that the structure of the disks themselves be highly controlled.
[0003] In the development of such devices, a common approach which is followed even today
for devices not used at the highest bit densities, provides a good example of the
properties desired for a high quality disk medium. That example is to coat an aluminum
disk with a slurry containing gamma ferric oxide, in which -the oxide consists of
needlelike particles approximately a micrometer in length and a tenth of micrometer
in width. Each needle consists of a variety of magnetic domains in acicular arrangement.
Resultant directional magnetization occurs when the needle particles are under an
external magnetic field. Alignment of the magnetic needles is achieved during the
disk manufacturing process by rotating the disk in a magnetic field which is perpendicular
to the plane of the disk before the slurry has dried. A resultant magnetic field in
small regions of the disk is then achieved when data are written, that writing being
accomplished when a magnetic transducer (a head) applies a magnetic field to a region
of the medium. When the field of the head is removed, the region of polarized medium
remains, thus making it possible to store information. The magnetization can be driven
back to zero, and beyond, to saturation in the opposite direction, by reversing the
magnetic field of the head. However, because magnetization persists in the medium,
the field reversal does not immediately reverse the polarity of the region in question,
i.e., hysteresis causes the reversal to lag the applied fieid.
[0004] For a magnetic medium, it is desirable that the remanent magnetization, M
R (i.e., the magnetism that persists when the magnetic field is absent), be large,
and that a moderately large field strength be necessary to demagnetize the medium
(i.e., that the coercive field strength H
C, be large). Also, it is important that reversal of the magnetization of the medium
be achieved over a small range of applied field strength, to ensure that magnetic
states of the medium that are used for data storage are well defined. Hence, important
attributes of a high quality magnetic recording medium are that the hysteresis loop
be large (typically having a saturation magnetization M on the order of 10,000 Gauss
and larger), with a coercivity greater than 500 oersteds, and have a squareness ratio,
M
R/MS' near 1.0 (typically above 0.8).
[0005] Although particulate layers are still used, it is apparent that improved magnetic
recording and storage devices can be achieved using solid magnetic films of materials
which can achieve a higher magnetization than particulate gamma ferric oxide in a
slurry. These films are chemically bonded to the substrate, so that no separate bonding
or filler material is required.
[0006] A typical approach in manufacturing such a thin-film metallic disk is to start with
an aluminum or aluminum alloy disk substrate which is finished to a surface having
only a slight topograph (e.g., <50 microns circumferentially and <10 microns radially)
by turning and heat-flattening. Then the substrate is coated with a non-magnetic material,
such as nickel or nickel phosphorous alloy, typically by electroless plating to a
thickness of about 50 microns. This non-magnetic surface is then polished to a mirror
finish (surface roughness <0.04 microns) using mechanical processes to remove nodules
that result from the electroless deposition leaving a final thickness of about 30
microns. Then a cobalt-nickel-phosphorous magnetic alloy is electroplated onto the
non-magnetic layer as the magnetic recording medium. This is typically followed then
by a coating of a protective layer such as a polysilicate film, or a polymer film,
and/or a lubricant. (See U.S. Patent 4,154,875, entitled "Process For Manufacturing
a Magnetic Record Member," by Yanagisawa, issued May 1, 1979; and
U.S. Patent 4,152,469 entitled "Method of Forming a Magnetic Recording and Storage
Device Having High Abrasion Resistance," by Allen, et al, issued May 1, 1979.) From
a commercial production point of view, such processes leave much to be desired. Most
importantly, three different types of a deposition processes are used, electroless
plating for the non-magnetic layer on the substrate, electroplating of the magnetic
recording layer, and often, sputtering for the protective layer. Plating systems generally
are difficult to control as to plating process parameters, and are generally environmentally
hazardous. Also, the polishing procedure for the electroless plating adds significant
incremental costs to the price of the disk. In addition, having to follow the plating
processes with a sputtering process is associated with excessive handling requirements
to transfer the recording members from one apparatus and environment to another.
[0007] In another approach, described in U.S. Patent 4,224,381, entitled "Abrasion Resistant
Magnetic Record Members," by Patel, et al, issued September 1980, an electroless plating
step is used as described above to apply a layer of non-magnetic nickel, or nickel
alloy over the substrate. Then the electroless deposit is annealed for one to eight
hours to create a hard semicrystalline magnetic layer, which is then followed by a
non-magnetic conductive shield layer before the recording layer is deposited. This
annealing process apparently eliminates the need for polishing as described earlier,
but at the expense of providing an additional layer in the structure. However, this
procedure, too, entails significant handling requirements because of the annealing
required to convert the nickel-containing layer adjacent the substrate, and is more
time-consuming than desired for a high volume commercial production environment.
[0008] Another approach to eliminate the polishing requirements for the nickel alloy layer
adjacent the substrate is described in U.S. Patent 4,,469,566, entitled "Method and
Apparatus For Producing Electroplated Magnetic Memory Disk and the Like," by Wray,
issued September 4, 1984. There the nickel alloy layer is electroplated rather than
electroless plated, the electroplating taking place through one or more openings to
directly provide a smooth, fine grain, layer which does not need to be polished. That
nickel alloy layer is then followed directly by a another electroplating operation
to deposit the magnetic recording medium. Although the times to produce a recording
medium by such a process are within commercial realization, the process is fraught
with all the difficulties inherent in electroplating operations as described earlier,
i.e., environmental hazards and difficulties in process control. Further, in this
particular application which uses a rotating mask to achieve uniformity of deposition,
the mask and drive system must operate in the extremely hostile environment of the
plating bath, which as a general rule, leads to mechanical difficulties over time.
[0009] Other efforts have been directed to eliminating entirely the nickel alloy layer adjacent
the substrate. However, these efforts have concentrated on the use of ferrites such
as Fe304 or gamma-Fe
2O
3, which are generally less corrosive than the nickel-cobalt alloys, but which generally
also have a lesser magnetization. In the typical approach for ferrites, an alpha-Fe
2O
3 layer is continuously formed using any of the procedures of vacuum deposition, i.e.,
chemical sputtering, co-precipitation, or chemical vapor deposition. The alpha-F
e20
3 is then reduced to Fe
30
4, which is oxidized, if desired, to produce gamma-Fe
2O
3, An inherent problem in such a process is that it is difficult to stably reduce alpha
-Fe203 to Fe
30
4 due to the narrow temperature range for reduction, the step often resulting in excessive
reduction of alpha-Fe203 to metallic iron. Also, it is difficult to control the temperature
adequately to produce gamma-Fe
203 with the desired magnetic properties. Even when the process is properly controlled,
the typical magnetic characteristics for a recording medium of gamma-Fe2o
3 is a coercive field strength of less than 400 Oe and a squareness ratio of less than
0.4. For modern medium high density recording, e.g., 12x10
6 bits/inch
2, such magnetic characteristics are unacceptable.
[0010] To improve the magnetic characteristics and to facilitate the production of such
iron-based magnetic recording layers, it has been typical to alloy the iron with other
materials, such as copper, cobalt, chromium, and niobium. In one such approach described
in
U.S. Patent 4,156,037, entitled "Process For Producing a Magnetic Recording Medium,"
by Hattori, et al, the squareness was increased to over 0.7 using an iron, copper,
niobium, cobalt alloy. Still, the coercive force was less than is often desired and
was a maximum of less than 400 Oe.
[0011] Another alloy system is described in U.S. Patent 4,245,008, entitled "Corrosion Resistant
Magnetic Recording Media," by Michaelsen, et al, issued January 13, 1981. In that
patent, a clad layer of a non-magnetic corrosion resistant alloy, such as stainless
steel, cobalt super alloy, titanium, or nickel- chromium alloys, is sputter-deposited
onto a finished aluminum alloy substrate. An undercoat layer, preferably of chromium
or titanium is then deposited onto the corrosion resistant clad layer to enhance the
magnetic properties of the magnetic recording layer to follow. It is also suggested
that in some cases the undercoat layer is not needed when the clad layer can establish
the desired magnetic properties. The magnetic recording layer is then vacuum deposited
by electron beam heating and is composed of a ferromagnetic alloy of iron, cobalt,
and chromium. A protective overcoat, such as rhodium, is then sputter-deposited over
the magnetic recording layer. Although excellent results with regard to squareness
were obtained with this method (greater than 0.95 in some examples), the corr- civity
was often below 300 Oe and was a maximum of only 380 Oe. A further drawback of this
approach is that it apparently requires two different kinds of vacuum deposition,
sputtering and electron beam heating, processes which are not generally performed
in a single apparatus.
[0012] In U.S. Patent 4,426,265, entitled "Method of Producing a Metallic Thin Film Magnetic
Disk," by Brunsch, et al, issued January 17, 1984, the clad layer of the Michaelsen,
et al, patent described above is eliminated, presumably since the corrosiveness of
the iron-cobalt-chromium magnetic layer used is not high, e.g., as compared to nickel-cobalt
magnetic layers. In Brunsch, et al, a chromium undercoat and the iron-cobalt-chromium
alloy magnetic layer are obliquely sputtered at an angle of about 60°, with the thickness
distribution being controlled by a sector shutter. The results achieved using the
method disclosed are quite good, e.g., up to 600 Oe coercive field strength. However,
the apparatus and method do not lend themselves easily to a production environment.
The disk to be deposited must be rotated within the housing so that the shutter may
control deposition thickness across the surface of the disk. Generally, rotating systems
are inherently more difficult to maintain than static ones and require regular and
intense maintenance in a sputtering environment. Furthermore, even with the shutter,
it appears impossible to obtain consistently high and uniform coercivity (i.e., >600
Oe) from the inside diameter to the outside diameter of the disk. In addition, highly
specialized apparatus and techniques are required to achieve the high oblique angle
of incidence.
Summary of the Invention
[0013] In accordance with preferred embodiments of the invention, a new high quality, low
cost, metallic thin-film magnetic recording member is provided, which has a coercive
field strength greater than 650 Oe, a saturation magnetization greater than 10,000
Gauss, and a squareness ratio of 0.9 or larger. The member includes a substrate on
which is directly sputter deposited a chromium layer, without the use of an intervening
nickel-containing layer between the substrate and the chromium. A nickel-cobalt recording
layer is then sputter deposited directly onto the chromium layer, and a protective
coating is typically deposited over the nickel-cobalt layer. In the preferred method
of the invention, the substrate is preheated before the chromium deposition to a temperature
in the range of 190 °C to 350 °C, and more preferably, to a temperature in the range
of 200°C to 330°C to drive off adsorbed gases, and to establish the proper conditions
for the chromium deposition. Also, during the time T between the termination of the
chromium deposition and the beginning of the nickel-cobalt deposition, the substrate
temperature is maintained in the range of 190°C to 350°C and more preferably in the
range of 200°C to 330°C. Also, time T is held to less than 5 minutes, and preferably
to less than 100 seconds, to ensure high quality magnetic properties. In the above
method, the heating steps and the sputtering steps are all carried out in a vacuum
of at least 5x10
-7 Torr, and preferably in a vacuum of about 1x10
-7 Torr, and without breaking vacuum between steps.
Brief Description of the Drawings
[0014]
Fig. 1 shows a typical disk according to the invention.
Fig. 2 shows a cross-sectional view of the disk of Fig. 1.
Fig. 3 illustrates the general layout of a Varian MDP-1000 disk sputtering apparatus.
Fig. 4 shows a floor plan of the main vacuum chamber of MDP-1000.
Fig. 5 illustrates the motion of a disk through the MDP-1000.
Fig. 6 shows a heated pedestal according to the invention.
Figs. 7A and 7B are graphs demonstrating the dependence of recording parameters on
substrate temperature during the manufacturing process.
Fig. 8 is a graph showing the coefficient of moving friction for a a typical disk
according to the invention.
Fig. 9 is a graph showing the coefficient of static friction for a typical disk according
to the invention.
Detailed Description of the Invention
[0015] In accordance with a preferred embodiment of the invention shown in Figs. 1 and 2
is a magnetic disk 10 such as might be used with a Winchester type head and drive
system. In the typical 51 inch implementation, the disk has concentric inner and outer
diameters, dl and d2, with inner diameter dl of about 40mm and outer diameter of about
130mm. The disk is typically chamfered at the outer edge of the outer diameter d2
and has a nominal thickness of about 75 mils (1.905mm). On both sides of the disk,
the region of magnetic surface over which magnetic heads may fly, i.e., the head flight
zone, extends from an inner radius r
3 of about 27.43mm maximum to an outer radius r
4 of about 63.50mm minimum. All of these dimensions will of course vary if the size
of the disk is changed from the typical 51 implementation, say to a 14 inch or 31
inch format.
[0016] As illustrated in the cross-sectional view of Fig. 2, the disk is a multilayered
structure symmetric on both sides about a substrate 11, having a chromium non-magnetic
layer 17 directly on the substrate 11, a magnetic nickel-cobalt layer 15 directly
on the chromium layer 17, and a protective layer 13 on the nickel-cobalt layer 15.
This is quite unlike prior art devices which use a nickel-cobalt magnetic layer, in
that there is no nickel-containing layer between the substrate and the chromium.
[0017] In the preferred mode, the substrate 11 is typically constructed of computer grade
aluminum alloy 5086 having a thickness of 75 mils + 1 mil (0.190cm + .003cm). However,
other materials such as pure aluminum, glass, plastic, or silicon may be used, and
the thickness may be varied depending on the desired stiffness and inertia and the
particular material used. The chromium non-magnetic layer 17 is critical to the structure,
and acts to provide the seed characteristics for the nickel-cobalt magnetic layer
15, (i.e., to set up a preferred magnetic structure for layer 15) while at the same
time inhibiting galvanic cell action between the nickel-cobalt layer and the substrate.
In the preferred mode, the chromium layer 17, has a minimum thickness of about 1000
A and a maximum thickness of about 4500 Ä, with a preferred nominal thickness of 2000
A + 20%. To be effective, the chromium layer should be quite pure, and preferably
should contain less than 0.5% by weight of other materials and should be free of cracks
and bubbles. In the preferred embodiment, the magnetic nickel-cobalt layer 15 has
a minimum thickness of 350 A and a maximum thickness of 1000 A, with a preferred nominal
thickness of 430 A + 10%. The nickel content of the magnetic layer 15 should be a
minimum of 15% and a maximum of 23% by weight, with a preferred nominal of 20.0% +
0.8% and preferably should have a purity of at least 99.9% nickel and cobalt. In the
preferred mode, the protective layer 13 is carbon, having a thickness in the range
of 300 A to 800 A, with a preferred nominal thickness of 600 A + 10%. Different materials
may also be used for the protective layer, e.g., preferrably sputterable materials
such as rhodium, A1
20
3, or Si0
2.
[0018] In the preferred method of constructing disk 10, the aluminum substrate is first
cleaned and polished to a surface topographic variation of less than 0.01 microns
using standard mechanical techniques. The thin-films are then applied using a Varian
Associates MDP-1000 disk sputtering system, illustrated in Figs. 3 and 4. In the standard
Varian implementation, the system includes a main chamber 11, for containing the various
sputtering magnetrons and transport mechanisms, and for maintaining an overall system
vacuum. In a typical Varian implementation, the main chamber is 12.5 inches high,
by 23 inches wide, by 96 inches long, and includes sputtering stations 1 through 4,
with stations 5 and 6 available as an option for additional sputtering needs. In the
preferred embodiment, all six stations are used, with station 1 serving as a preheating
station to drive off adsorbed gases, station 2 for sputtering chromium, station 5
for sputtering nickel-cobalt, and stations 3, 4 and 6 for sputtering carbon for the
protective layer. An alternative embodiment is with station 3, 4 or 6 being inactive.
In the typical Varian implementation, each sputtering station uses a pair of horizontally
opposed magnetrons, with circular target geometry, known in the art as the Varian
M-Gun design. By using two magnetrons in the horizontally opposed configuration with
the disk held vertically therebetween, both sides of the disk are sputter coated simultaneously.
Also, the vertical orientation of the disk throughout the entire process minimizes
particulate collection.
[0019] In the standard Varian system, the apparatus is equipped with an automated transport
system, the motion of which is illustrated in the side view chamber 11 shown in
Fig. 5. Disks are automatically transferred one at a time from a standard 25-disk cassette
28 into a load lock chamber 29. The load lock chamber 29 is then pumped down, and
the disk is lowered into the main chamber 11 by a vertical actuator 31. On command,
the disk is then transferred by a transport system (not shown) to a vertical actuator
32 beneath station 1, and is raised into position within that station. After preheating
in station 1, the actuator 32 lowers the disk, and the transport system moves the
disk to a fixed pedestal 33. The transport system then moves the disk from pedestal
33 to an actuator 34, which moves the disk upwards into station 2. After deposition
in station 2, the disk is moved as before to a fixed pedestal 35, then to actuator
36, and then upwards into station 5. After deposition in station 5, the disk is then
moved as before to a fixed pedestal 37 from whence a rotating arm 38 picks up the
disk and transports it 180 degrees to a pedestal 39 located at inactive station 6.
This process then continues from actuator, to station, to actuator, to pedestal, until
the disk is unloaded into a load lock chamber 49 and finally into a waiting cassette
holder 48'. At each transfer step from actuator to pedestal, a new disk is moved into
the system so that eventually the system is full, i.e., with one disk associated with
each activator and one disk with each pedestal, and the process becomes quasi-continuous,
with one disk being unloaded each time a new disk is loaded. Typically, all disks
are advanced in unison from one position to the next, either horizontally or vertically.
For example, as disk 10 is lowered from station 1, so will disks 14 and 18 be lowered
from their respective stations. Then at the same time, a new disk is moved onto actuator
32, disk 10 will be moved to pedestal 32, disk 12 will be moved to actuator 34, disk
14 will be moved to pedestal 35, etc. In this way, successive layers can be sputtered
onto the disk without breaking the primary vacuum on chamber 11, and a continuous
throughput can be achieved.
[0020] In the preferred embodiment, a modification has been made to the standard apparatus
described above as illustrated in Fig. 5. Shown there is a typical fixed pedestal
as provided by Varian Associates, such as 33, having a notch 53, in order to vertically
support a disk by its chamfered edge. In the preferred mode, this standard pedestal
is altered by providing a resistive heating element 55 which is placed in contact
with the metallic pedestal, and is secured to the pedestal by means of screws. The
resistive elements are available as stock number PT512 from Chromaloy, and generally
have a power rating of 125 watts. However, other resistors may, of course, be used.
Temperature control of the pedestals is achieved by monitoring the pedestal with a
thermocouple, and varying the voltage across the resistive elements to achieve the
desired result.
[0021] In the preferred method of producing high quality disks with the above-described
apparatus, the pressure in the main chamber 11 is first reduced to less than 2x10
-7 Torr, and preferably to below 1x10
-7 Torr, as measured on a Varian 860 cold cathode gauge, and the system is checked to
ensure that the following readings are obtained on a residual gas analyzer such as
Inficon Model 017-450-G1; 0
2 (mass
32) less than 0.3x10
-12,
H20 (mass 18) less than 1.5x10
-12, N
2 less than 2.0x10
-12, and H
2(
ma
ss
2) less than 10.0x10
-12. Similarly, the individual stations 1-5 are pumped by their individual cryopumps
to achieve a gas pressure therein of less than 5x10
-7 Torr or lower, and all cryopumps are stabilized at a temperature of less than 15°K.
The fixed pedestals are preferably heated to temperature of between 190°C and 350°C,
and more preferably, to a temperature between 200°C and 330 °C, as measured by a Fluke
thermocouple meter, and allowed to stabilize (typically about 30 minutes). Standard
procedures are used to ensure adequate cooling water to the station sputtering magnetrons,
and gas lines for nitrogen, argon, and compressed air, are monitored to ensure adequate
pressure. To begin the processing, loaded cassette 28 is then blown off with nitrogen
and is placed in the proper position to be unloaded, disk by disk, into the main chamber
11, the sequence of operations proceding as described above. At station 1, disks are
preheated for about 35 seconds to a temperature of 200°C to 330°C to cause desorption
of absorbed gases and to precondition the disk for the direct sputtering of the chromium
layer 17 to follow.
[0022] The chromium layer is sputter deposited in station 2 using an argon flow rate of
20ml/min. + 10% and argon pressure of less than 15 mTorr, with a cathode voltage of
550 volts and a target current of 8 amps + 10%. The typical deposition rate is about
3000 A/min., and the sputtering time is generally about 40 seconds, to achieve the
nominal 2000 A of chromium. Other voltages, currents and times can be used to give
the same thickness of chromium. A typical target for the chromium deposition is part
number 02000-24-000-00A, available from Varian Associates, which is of Grade A purity
(>99.5% chromium by weight), having less than 250 parts per million of other materials
therein, other than oxygen.
[0023] The nickel-cobalt layer 15 is sputter deposited in station 3, using an argon flow
rate of l7ml/min. + 10%, and an argon pressure of less than 15 mTorr, with a cathode
voltage of 550 volts and a target current of 2.4 amps + 5%. The sputtering time is
typically about 22 seconds and the preferred deposition rate is about 1090 A/min.
to achieve the preferred nominal nickel. chromium thickness of 400 A. A typical target
for the nickel-cobalt deposition is part number 03100-27-003-300 available from Varian
Associates, having a nominal nickel to cobalt ratio of 20 to 80, with an admixture
of impurities of less than 200 parts per million.
[0024] The carbon deposition is performed in three stages as indicated earlier, the first
stage in station 6, the second stage in station 3, and the third stage in station
4, since the carbon deposition rate is much lower than the metal deposition rates,
only about 480 A/min. In all three stations, the typical cathode voltage is 550 volts,
the target current is 4.1 amps + 10%, and the total sputtering time at each station
is about 25 seconds to achieve a total preferred nominal thickness of 600 A. Again,
the argon pressure is maintained below 15 mTorr in both stations, however, the argon
flow rate is maintained at about 18ml/min. in station 3, and at about 22ml/min. in
station 4. A typical target for the carbon deposition is Spectrographic grade carbon,
having a purity of 99.999%, e.g., available from Sputtering Materials, Inc. in Santa
Clara, California.
[0025] Another important element of the method of invention is the transport time used between
stations, in particular, between the chromium station 2 and the nickel-cobalt station
5. This is due to the fact that the chromium layer 17 acts to set up the seed characteristics
for the preferred crystallographic configuration of the nickel-cobalt layer 15 as
it is being deposited. A possible intrepretation is that the chromium is instrumental
in establishing a single phase hexagonal close packed magnetic structure for the nickel-cobalt
layer, although other interpretations may be possible. To achieve the preferred configuration,
it is important that the deposition of the nickel-cobalt layer 15 be begun only a
short time after the chromium layer 17 is deposited, typically within at most a few
minutes, (<5 minutes), preferably within less than 100 seconds, and more preferably
within 70 seconds or less, after deposition of the chromium layer, and that the surface
of the chromium be maintained in high vacuum as described above. Although the mechanism
is not completely understood, it is thought that the reason for this time dependence
is the formation of oxides on the chromium surface before the nickel-cobalt is sputtered
thereon. With the Varian MDP-1000, the transit time between successive positions in
the main chamber can be made as low as 15 seconds on a consistent basis, thereby ensuring
a time lapse between the end of the chromium deposition on a disk and the beginning
of the nickel-cobalt deposition on that same disk of about 70 seconds (15 seconds
for movement between station 2 and pedestal 35, 40 seconds for sputtering the following
disk in station 2, and another 15 seconds for movement of the disk from pedestal 35
to station 5 for nickel-cobalt deposition).
[0026] With the above high throughput method, disks of high quality are obtained at a relatively
low cost. In the typical (prior art) manufacturing situation, the substrate is purchased
with a layer of nickel alloy already on the aluminum surface of the substrate, adding
an incremental cost of at least three dollars per disk over the cost of a similarly
finished aluminum substrate without a nickel alley laver thereon. Hence, by eliminating
the nickel alloy layer, the invention provides a substantial cost savings for high
volume production.
[0027] As an example of the quality, a typical disk produced by the above method using the
preferred nominal values of the various parameters displays a high satur-, ation magnetization,
M
S, over 10,000 Gauss, and a high coercive field strength, Hc, of 650 Oe at the outer
diameter of the disk, with a variation from the inner to outer diameter of the head
flight zone of at most 8% radially and at most 4% circumferentially (as measured using
a vibrating sample magnetometer). Also, the resulting squareness ratio, i.e., M
S to the remanent magnetization M
R, is typically greater than 0.9, with a disk to disk variation of at most 5%.
[0028] To illustrate the importance of preheating the disks appropriately in achieving desired
magnetic properties, Figs. 7A and 7B show the changes in typical recording parameters
as a function of the preheating temperature of the-substrate in station 1. Shown in
Fig. 7A is a plot of the average track amplitude, hereinafter V
2f, recorded at a frequency 2f = (5000+5)x10
3 transitions/second, as a function of preheating temperature, the measurements being
obtained using a relatively standard head having a monolithic Mn-Zn ferrite slider
with a nominal gap width of 25.4 micrometers, a nominal gap length of 1.1 micrometers,
having a nominal inductance of 14 microhenries in air at 1 MHz, at a nominal flying
height of 0.41 micrometers at the innermost radius of the head flight zone. As illustrated
V
2f generally increases substantially as the preheating temperature is increased.
[0029] Fig. 7
B is a graph of the resolution as a function of preheating temperature for several
different pressures in the main chamber. (Resolution is defined as the ratio of
V2f to V
lf, where V
lf is the average track amplitude recorded at a frequency If = (2500+2.5)xl0
3 transitions per second.) As shown, the resolution increases substantially as the
temperature increases. Also, as the vacuum in the main chamber degrades, i.e., as
it goes from 1x10
-7 Torr to 5x10
-7 Torr, a substantial increase in preheating temperature is required to achieve the
same resolution. From the graph, it is apparent that to maintain a resolution above
60% even for a good vacuum, i.e. 1x10
-7 Torr, requires a temperature of about 190°C and to obtain a resolution of over 70%
requires a preheating temperature of well over 200°C. For the system where the vacuum
is not as good, e.g., for a main chamber pressure of 5x10
-7 Torr, to have a resolution of over 60% requires a preheating temperature of about
250°C and higher, and for a resolution approaching 70% (68%) requires a temperature
of about 330°C. Higher preheating temperatures do not appear to substantially enhance
the recording characteristics in the main chamber and as an upper limit on preheating
temperatures, 350°C appears to be a practical maximum based on physical considerations
with respect to the surface characteristics of the aluminum substrate. Above that
temperature, local deformations of the aluminum surface appear to cause deleterious
effects on the later deposited layers. Hence, the preferred range of temperatures
for preheating is from 190°C to 350°C, with an even more preferred range of 200°C
to 330°C when using main chamber pressures in the range of lxl0"
7 Torr to 5x10
-7 Torr. For pressures below 1x10
-7 Torr (using the cycle time between the termination of the chromium sputtering and
the initiation of the nickel-cobalt sputtering of 70 seconds or less), the recording
characteristics do not change appreciably with temperature compared with those represented
by the curves corresponding to a pressure of 1x10
-7 Torr. Hence, for pressures at 1x10
-7 Torr and below, the preferred temperature range is the same.
[0030] In addition, tests illustrated in Figs. 8 and 9, demonstrate that a disk produced
by the above method exhibits very low friction coefficients. For example, friction
coefficient V, is consistently less than 0.1, where µ
1 = f
l/F, f
l is the absolute friction force measured with the disk rotating at a relative velocity
of 15 + 0.5 inches per second, and the head load F is 9.5 - 10.5gm. Also, the coefficient
µ
2 = f
2/F, where the relative friction force f2, taken across the height of. the force trace
of Figure 8, peak-to-peak, is less than 0.03. The static friction P
3 = f
3/F, where f
3 is the static friction force is less than 0.25, and is measured during the first
rotation of the disk and is taken from the zero position to the maximum value of the
force trace. Also, the measurement is taken after a minimum period of 24 hours of
contact.
[0031] Those skilled in the art will appreciate that there are many variations to the general
method which are encompassed by the invention. For example, chromium deposition can
be broken down into two steps. Such an alteration would merely involve sputtering
chromium in stations 2 and 5, sputtering CoNi in station 6, and adding a heating element
to the rotating arm 38. In addition, materials other than aluminum alloy may be used
for the substrate, and materials other than carbon may be used for the protective
layer. Also, it should be appreciated that the method of the invention is not restricted
to use with the Varian MDP-1000 which is merely a convenient vehicle for carrying
it out. All that is required is that the sequence of chromium and nickel-cobalt sputtering
steps be able to be carried out without breaking vacuum and that the appropriate heating
can be ensured.
1. A magnetic recording element comprising:
a substrate having at least one supporting surface, said supporting surface not having
a nickel-containing layer thereon;
a chromium layer sputter-deposited directly onto said supporting surface;
a nickel-cobalt magnetic recording layer sputter-deposited directly onto said chromium
layer; and
a protective layer deposited onto said nickel-cobalt magnetic recording layer.
2. A recording element as in claim 1, wherein said chromium layer comprises at least
99.5% by weight of pure chromium.
3. A recording element as in claim 2 wherein said nickel-cobalt layer comprises at
least 99.9% by weight of nickel and cobalt.
4. A recording element as in claim 1 wherein said nickel-cobalt layer comprises at
least 15% and at most 23% by weight of nickel.
5. A recording element as in claim 4 wherein said chromium layer is a minimum of 1000
A thick and a maximum of 4500 A thick.
6. A recording element as in claim 5 wherein said chromium layer has a thickness of
2000 A + 20%.
7. A recording element as in claim 5 wherein said nickel-cobalt layer is a minimum
of 350 A and a maximum of 1000 A.
8. A recording element as in claim 7 wherein said nickel-cobalt layer is 400 A + 10%.
9. A method of constructing a thin-film disk recording device comprising:
heating a substrate to a temperature in the range of 190°C to 350°C, said substrate
having a surface which does not have a nickel-containing layer thereon;
sputtering chromium directly onto said surface during a first preselected time to
form a chromium layer on said substrate;
sputtering a nickel-cobalt magnetic layer onto said chromium layer during a second
preselected time;
heating said substrate and chromium layer thereon during the time between said first
preselected time and said second preselected time; and
depositing a protective layer over said nickel-cobalt layer.
10. A method as in claim 9 wherein the step of heating during the time between said
first preselected time and said second preselected time comprises placing said substrate
with said chromium layer thereon on a heated pedestal.
ll. A method as in claim 10 wherein said heated pedestal has a temperature in the
range of 190°C to 350°C.
12. A method as in claim 11 wherein the temperature of said pedestal is between 200°C
and 330°C.
13. A method as in claim 12 wherein said chromium layer consists of at least 99.5%
by weight of chromium.
14. A method as in claim 13 wherein said nickel-cobalt layer consists of at least
99.9% by weight of nickel and cobalt.
15. A method as in claim 11 wherein the time between said first preselected time and
said second preselected time is less than 50 minutes.
16. A method as in claim 15 wherein said time between said first preselected time
and said second preselected time is less than 100 seconds.
17. A method as in claim 9 wherein said sputtering steps are carried out in a vacuum
of at least 5x10-7 Torr.
18. A method as in claim 17 wherein said heating steps and said sputtering steps are
carried out without breaking said vacuum.
19. A method as in claim 18 wherein said vacuum is at least 1x10-7 Torr.